Building energy simulation coupled with CFD for indoor environment: A critical review and recent applications

Tian, Wei; Han, Xu; Zuo, Wangda; Sohn, Michael D.

doi:10.1016/j.enbuild.2018.01.046

Cited by 106 publications

(53 citation statements)

References 63 publications

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“…Although this does not reflect physical reality well, the only current alternative is computational fluid dynamics (CFD)-a complex and computationally intensive simulation of air movement (Crawley et al 2001). Several studies have shown that the improvement in modeling accuracy from using CFD for building energy simulations is negligible compared to the increase in time and computational power required to run such models (Martinet al 2017;Tan & Glicksman 2005;Tian et al 2018;Zhai et al 2002). CFD models look at the thermal zone at a discretized level by breaking it into large amounts of control volumes, which is not useful for running annual simulations of the whole building (Martin et al 2017).…”

Section: Modeling Thermal Bridging and Infiltrationmentioning

confidence: 99%

Wall Upgrades for Residential Deep Energy Retrofits: A Literature Review

Antonopoulos

Metzger

Zhang

et al. 2019

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In the United States, 39% of total energy is consumed by the building sector, 20% of the total is attributed to residential buildings (U.S. Energy Information Administration, 2018). New, highperformance homes incorporate a combination of tight building envelopes, mechanical ventilation, and efficient components to ensure comfort, adequate airflow, and moisture control. These systems work together to create energy efficient homes that use measures to manage moisture, comfort, energy efficiency, and the indoor environment. Older homes, built before 1992 when the U.S. Department of Energy's Building Energy Codes Program was established represent approximately 68% of residential building stock in the country and often have significant air leakage and inadequate insulation. Homes with little to no air sealing or insulation have heating and cooling losses that can represent a substantial portion of utility bills. Done correctly, deep energy retrofits can significantly improve the energy performance of a home's thermal envelope, and increase homeowner comfort and health. This literature review summarizes current practices for exterior wall retrofits for existing homes, provides an overview of techno-economic approaches to investigating residential wall systems, and discusses thermal and hygrothermal modeling strategies. This literature review is part of a larger effort to identify state-of-the-art technologies for energy efficient wall retrofit systems that are suitable for cold and very cold climate zones. Retrofit wall systems that can be applied over existing siding offer a possible approach to reducing installation costs.

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Section: Modeling Thermal Bridging and Infiltrationmentioning

confidence: 99%

Wall Upgrades for Residential Deep Energy Retrofits: A Literature Review

Antonopoulos

Metzger

Zhang

et al. 2019

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“…Comprehensive review of the literature regarding the coupled simulation of building energy systems and the indoor environment (Tian et al, 2018) indicates that the previous studies only focused on the integration of air handler units with indoor environment, whereas none of these studies ever took into account the dynamics of vapor compression systems, which are the essential part of building HVAC systems through which heat is removed from or added to buildings. Also, they are the primary energy consumer compared to other auxiliary components, such as pumps and fans.…”

Section: 3384/ecp19157265mentioning

confidence: 99%

Coupled Simulation of a Room Air-conditioner with CFD Models for Indoor Environment

Qiao

Han

Nabi

et al. 2019

Linköping Electronic Conference Proceedings

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Coupled simulation of building energy systems (BES) and computation fluid dynamics (CFD) often focuses on the integration of air handlers with indoor environment, and does not incorporate vapor compression systems into the analysis, yielding inaccurate prediction of building energy consumption. This paper presents a coupled simulation to explore the pull-down performance of a room air conditioning system. The dynamic models of the air-conditioner are constructed in Modelica, whereas the indoor environment is simulated in OpenFOAM. Dynamic characteristics will be compared with different vane angles and airflow modes. Numerical simulations demonstrate that both vane angle and airflow mode exhibit pronounced impact on the pull-down time. Meanwhile, the well-mixed assumption that most of building energy simulation programs are built upon exhibits drastically different dynamic characteristics compared to the detailed CFD model, suggesting that neglecting non-uniform air flow and temperature distributions in buildings might lead to significant errors in control design.

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“…Sustainability has become a significant factor in the building sector [1][2][3], integrating such aspects as design, construction, rehabilitation and operation. In the field of building simulations, researchers are looking for new information to obtain a more efficient building depending on the location and its climatology [4][5][6], and thus make energetic savings.…”

Section: Introductionmentioning

confidence: 99%

Simulation and Thermo-Energy Analysis of Building Types in the Dominican Republic to Evaluate and Introduce Energy Efficiency in the Envelope

et al. 2020

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The improvement of the energy performance in buildings is key for sustainable development, even more so in the case of the Dominican Republic (DR), which is committed to this goal but which has neither regulation nor specific social behavior in this field. The main goal of this work is double; on one hand it is aimed at providing useable information for those who have the responsibly of making regulation norms and on the other, it is desirable to give an essential, technically proven and handy tool to those involved in the construction sector in improving the envelopes of buildings and to introduce good practices into the management of the energy systems of buildings. A case study of eight administrative buildings located in different climatic zones of the DR was carried out. A simulation tool was used for the study, and one of the buildings was monitored to verify the simulation work. Those factors that affect the development of the buildings in relation to thermo-energy consumption have been detailed. The large-scale heat gains resulting from the common glazing used by the tertiary sector in the Dominican Republic (including office buildings, hospitals and shops among others) illustrate the need for economically viable solutions in this sector. As a conclusion, it has been proved that the incidental thermal load of buildings could be reduced by up to 40%, thus in turn reducing the costs associated with the electricity needed to maintain the users’ desired thermal comfort level, as their influence in this sector is significant.

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Building energy simulation coupled with CFD for indoor environment: A critical review and recent applications

Cited by 106 publications

References 63 publications

Wall Upgrades for Residential Deep Energy Retrofits: A Literature Review

Wall Upgrades for Residential Deep Energy Retrofits: A Literature Review

Coupled Simulation of a Room Air-conditioner with CFD Models for Indoor Environment

Simulation and Thermo-Energy Analysis of Building Types in the Dominican Republic to Evaluate and Introduce Energy Efficiency in the Envelope

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